import numpy as np
from scipy.stats import norm
from numba import njit, guvectorize
import scipy.linalg
import re
import inspect

'''Part 1: Efficient linear interpolation exploiting monotonicity.

    Interpolates increasing query points xq against increasing data points x.

    - interpolate_y: (x, xq, y) -> yq
        get interpolated values of yq at xq

    - interpolate_coord: (x, xq) -> (xqi, xqpi)
        get representation xqi, xqpi of xq interpolated against x
        xq = xqpi * x[xqi] + (1-xqpi) * x[xqi+1]

    - apply_coord: (xqi, xqpi, y) -> yq
        use representation xqi, xqpi to get yq at xq
        yq = xqpi * y[xqi] + (1-xqpi) * y[xqi+1]

    Composing interpolate_coord and apply_coord gives interpolate_y.

    All three functions are written for vectors but can be broadcast to other dimensions
    since we use Numba's guvectorize decorator. In these cases, interpolation is always
    done on the final dimension.
'''


@guvectorize(['void(float64[:], float64[:], float64[:], float64[:])'], '(n),(nq),(n)->(nq)')
def interpolate_y(x, xq, y, yq):
    """Efficient linear interpolation exploiting monotonicity.

    Complexity O(n+nq), so most efficient when x and xq have comparable number of points.
    Extrapolates linearly when xq out of domain of x.

    Parameters
    ----------
    x  : array (n), ascending data points
    xq : array (nq), ascending query points
    y  : array (n), data points

    Returns
    ----------
    yq : array (nq), interpolated points
    """
    nxq, nx = xq.shape[0], x.shape[0]

    xi = 0
    x_low = x[0]
    x_high = x[1]
    for xqi_cur in range(nxq):
        xq_cur = xq[xqi_cur]
        while xi < nx - 2:
            if x_high >= xq_cur:
                break
            xi += 1
            x_low = x_high
            x_high = x[xi + 1]

        xqpi_cur = (x_high - xq_cur) / (x_high - x_low)
        yq[xqi_cur] = xqpi_cur * y[xi] + (1 - xqpi_cur) * y[xi + 1]


@guvectorize(['void(float64[:], float64[:], uint32[:], float64[:])'], '(n),(nq)->(nq),(nq)')
def interpolate_coord(x, xq, xqi, xqpi):
    """Get representation xqi, xqpi of xq interpolated against x:
    xq = xqpi * x[xqi] + (1-xqpi) * x[xqi+1]

    Parameters
    ----------
    x    : array (n), ascending data points
    xq   : array (nq), ascending query points

    Returns
    ----------
    xqi  : array (nq), indices of lower bracketing gridpoints
    xqpi : array (nq), weights on lower bracketing gridpoints
    """
    nxq, nx = xq.shape[0], x.shape[0]

    xi = 0
    x_low = x[0]
    x_high = x[1]
    for xqi_cur in range(nxq):
        xq_cur = xq[xqi_cur]
        while xi < nx - 2:
            if x_high >= xq_cur:
                break
            xi += 1
            x_low = x_high
            x_high = x[xi + 1]

        xqpi[xqi_cur] = (x_high - xq_cur) / (x_high - x_low)
        xqi[xqi_cur] = xi


@guvectorize(['void(int64[:], float64[:], float64[:], float64[:])',
              'void(uint32[:], float64[:], float64[:], float64[:])'], '(nq),(nq),(n)->(nq)')
def apply_coord(x_i, x_pi, y, yq):
    """Use representation xqi, xqpi to get yq at xq:
    yq = xqpi * y[xqi] + (1-xqpi) * y[xqi+1]

    Parameters
    ----------
    xqi  : array (nq), indices of lower bracketing gridpoints
    xqpi : array (nq), weights on lower bracketing gridpoints
    y  : array (n), data points

    Returns
    ----------
    yq : array (nq), interpolated points
    """
    nq = x_i.shape[0]
    for iq in range(nq):
        y_low = y[x_i[iq]]
        y_high = y[x_i[iq]+1]
        yq[iq] = x_pi[iq]*y_low + (1-x_pi[iq])*y_high


'''Part 2: More robust linear interpolation that does not require monotonicity in query points.

    Intended for general use in interpolating policy rules that we cannot be sure are monotonic.
    Only get xqi, xqpi representation, for case where x is one-dimensional, in this application.
'''


def interpolate_coord_robust(x, xq, check_increasing=False):
    """Linear interpolation exploiting monotonicity only in data x, not in query points xq.
    Simple binary search, less efficient but more robust.
    xq = xqpi * x[xqi] + (1-xqpi) * x[xqi+1]

    Main application intended to be universally-valid interpolation of policy rules.
    Dimension k is optional.

    Parameters
    ----------
    x    : array (n), ascending data points
    xq   : array (k, nq), query points (in any order)

    Returns
    ----------
    xqi  : array (k, nq), indices of lower bracketing gridpoints
    xqpi : array (k, nq), weights on lower bracketing gridpoints
    """
    if x.ndim != 1:
        raise ValueError('Data input to interpolate_coord_robust must have exactly one dimension')

    if check_increasing and np.any(x[:-1] >= x[1:]):
        raise ValueError('Data input to interpolate_coord_robust must be strictly increasing')

    if xq.ndim == 1:
        return interpolate_coord_robust_vector(x, xq)
    else:
        i, pi = interpolate_coord_robust_vector(x, xq.ravel())
        return i.reshape(xq.shape), pi.reshape(xq.shape)


@njit
def interpolate_coord_robust_vector(x, xq):
    """Does interpolate_coord_robust where xq must be a vector, more general function is wrapper"""

    n = len(x)
    nq = len(xq)
    xqi = np.empty(nq, dtype=np.uint32)
    xqpi = np.empty(nq)

    for iq in range(nq):
        if xq[iq] < x[0]:
            ilow = 0
        elif xq[iq] > x[-2]:
            ilow = n-2
        else:
            # start binary search
            # should end with ilow and ihigh exactly 1 apart, bracketing variable
            ihigh = n-1
            ilow = 0
            while ihigh - ilow > 1:
                imid = (ihigh + ilow) // 2
                if xq[iq] > x[imid]:
                    ilow = imid
                else:
                    ihigh = imid

        xqi[iq] = ilow
        xqpi[iq] = (x[ilow+1] - xq[iq]) / (x[ilow+1] - x[ilow])

    return xqi, xqpi


'''Part 3: Forward iteration of distribution on grid and related functions.

        - forward_step_1d
        - forward_step_2d
            - apply law of motion for distribution to go from D_{t-1} to D_t

        - forward_step_shock_1d
        - forward_step_shock_2d
            - forward_step linearized, used in part 1 of fake news algorithm to get curlyDs

        - forward_step_transpose_1d
        - forward_step_transpose_2d
            - transpose of forward_step, used in part 2 of fake news algorithm to get curlyPs
    '''

@njit
def forward_step_1d(D, Pi_T, x_i, x_pi):
    """Single forward step to update distribution using exogenous Markov transition Pi and
    policy x_i and x_pi for one-dimensional endogenous state.

    Efficient implementation of D_t = Lam_{t-1}' @ D_{t-1} using sparsity of the endogenous
    part of Lam_{t-1}'.

    Note that it takes Pi_T, the transpose of Pi, as input rather than transposing itself;
    this is so that when it is applied repeatedly, we can precalculate a transpose stored in
    correct order rather than a view.

    Parameters
    ----------
    D : array (S*X), beginning-of-period distribution over s_t, x_(t-1)
    Pi_T : array (S*S), transpose Markov matrix that maps s_t to s_(t+1)
    x_i : int array (S*X), left gridpoint of endogenous policy
    x_pi : array (S*X), weight on left gridpoint of endogenous policy

    Returns
    ----------
    Dnew : array (S*X), beginning-of-next-period dist s_(t+1), x_t
    """

    # first update using endogenous policy
    nZ, nX = D.shape
    Dnew = np.zeros_like(D)
    for iz in range(nZ):
        for ix in range(nX):
            i = x_i[iz, ix]
            pi = x_pi[iz, ix]
            d = D[iz, ix]
            Dnew[iz, i] += d * pi
            Dnew[iz, i+1] += d * (1 - pi)

    # then using exogenous transition matrix
    return Pi_T @ Dnew


def forward_step_2d(D, Pi_T, x_i, y_i, x_pi, y_pi):
    """Like forward_step_1d but with two-dimensional endogenous state, policies given by x and y"""
    Dmid = forward_step_endo_2d(D, x_i, y_i, x_pi, y_pi)
    nZ, nX, nY = Dmid.shape
    return (Pi_T @ Dmid.reshape(nZ, -1)).reshape(nZ, nX, nY)


@njit
def forward_step_endo_2d(D, x_i, y_i, x_pi, y_pi):
    """Endogenous update part of forward_step_2d"""
    nZ, nX, nY = D.shape
    Dnew = np.zeros_like(D)
    for iz in range(nZ):
        for ix in range(nX):
            for iy in range(nY):
                ixp = x_i[iz, ix, iy]
                iyp = y_i[iz, ix, iy]
                beta = x_pi[iz, ix, iy]
                alpha = y_pi[iz, ix, iy]

                Dnew[iz, ixp, iyp] += alpha * beta * D[iz, ix, iy]
                Dnew[iz, ixp+1, iyp] += alpha * (1 - beta) * D[iz, ix, iy]
                Dnew[iz, ixp, iyp+1] += (1 - alpha) * beta * D[iz, ix, iy]
                Dnew[iz, ixp+1, iyp+1] += (1 - alpha) * (1 - beta) * D[iz, ix, iy]
    return Dnew


@njit
def forward_step_shock_1d(Dss, Pi_T, x_i_ss, x_pi_shock):
    """forward_step_1d linearized wrt x_pi"""
    # first find effect of shock to endogenous policy
    nZ, nX = Dss.shape
    Dshock = np.zeros_like(Dss)
    for iz in range(nZ):
        for ix in range(nX):
            i = x_i_ss[iz, ix]
            dshock = x_pi_shock[iz, ix] * Dss[iz, ix]
            Dshock[iz, i] += dshock
            Dshock[iz, i + 1] -= dshock

    # then apply exogenous transition matrix to update
    return Pi_T @ Dshock


def forward_step_shock_2d(Dss, Pi_T, x_i_ss, y_i_ss, x_pi_ss, y_pi_ss, x_pi_shock, y_pi_shock):
    """forward_step_2d linearized wrt x_pi and y_pi"""
    Dmid = forward_step_shock_endo_2d(Dss, x_i_ss, y_i_ss, x_pi_ss, y_pi_ss, x_pi_shock, y_pi_shock)
    nZ, nX, nY = Dmid.shape
    return (Pi_T @ Dmid.reshape(nZ, -1)).reshape(nZ, nX, nY)


@njit
def forward_step_shock_endo_2d(Dss, x_i_ss, y_i_ss, x_pi_ss, y_pi_ss, x_pi_shock, y_pi_shock):
    """Endogenous update part of forward_step_shock_2d"""
    nZ, nX, nY = Dss.shape
    Dshock = np.zeros_like(Dss)
    for iz in range(nZ):
        for ix in range(nX):
            for iy in range(nY):
                ixp = x_i_ss[iz, ix, iy]
                iyp = y_i_ss[iz, ix, iy]
                alpha = x_pi_ss[iz, ix, iy]
                beta = y_pi_ss[iz, ix, iy]

                dalpha = x_pi_shock[iz, ix, iy] * Dss[iz, ix, iy]
                dbeta = y_pi_shock[iz, ix, iy] * Dss[iz, ix, iy]

                Dshock[iz, ixp, iyp] += dalpha * beta + alpha * dbeta
                Dshock[iz, ixp+1, iyp] += dbeta * (1-alpha) - beta * dalpha
                Dshock[iz, ixp, iyp+1] += dalpha * (1-beta) - alpha * dbeta
                Dshock[iz, ixp+1, iyp+1] -= dalpha * (1-beta) + dbeta * (1-alpha)
    return Dshock


@njit
def forward_step_transpose_1d(D, Pi, x_i, x_pi):
    """Transpose of forward_step_1d"""
    # first update using exogenous transition matrix
    D = Pi @ D

    # then update using (transpose) endogenous policy
    nZ, nX = D.shape
    Dnew = np.zeros_like(D)
    for iz in range(nZ):
        for ix in range(nX):
            i = x_i[iz, ix]
            pi = x_pi[iz, ix]
            Dnew[iz, ix] = pi * D[iz, i] + (1-pi) * D[iz, i+1]
    return Dnew


def forward_step_transpose_2d(D, Pi, x_i, y_i, x_pi, y_pi):
    """Transpose of forward_step_2d."""
    nZ, nX, nY = D.shape
    Dmid = (Pi @ D.reshape(nZ, -1)).reshape(nZ, nX, nY)
    return forward_step_transpose_endo_2d(Dmid, x_i, y_i, x_pi, y_pi)


@njit
def forward_step_transpose_endo_2d(D, x_i, y_i, x_pi, y_pi):
    """Endogenous update part of forward_step_transpose_2d"""
    nZ, nX, nY = D.shape
    Dnew = np.empty_like(D)
    for iz in range(nZ):
        for ix in range(nX):
            for iy in range(nY):
                ixp = x_i[iz, ix, iy]
                iyp = y_i[iz, ix, iy]
                alpha = x_pi[iz, ix, iy]
                beta = y_pi[iz, ix, iy]

                Dnew[iz, ix, iy] = (alpha * beta * D[iz, ixp, iyp] + alpha * (1-beta) * D[iz, ixp, iyp+1] +
                                    (1-alpha) * beta * D[iz, ixp+1, iyp] +
                                    (1-alpha) * (1-beta) * D[iz, ixp+1, iyp+1])
    return Dnew


'''Part 4: grids and Markov chains'''


def agrid(amax, n, amin=0):
    """Create grid between amin-pivot and amax+pivot that is equidistant in logs."""
    pivot = np.abs(amin) + 0.25
    a_grid = np.geomspace(amin + pivot, amax + pivot, n) - pivot
    a_grid[0] = amin  # make sure *exactly* equal to amin
    return a_grid


def stationary(Pi, pi_seed=None, tol=1E-11, maxit=10_000):
    """Find invariant distribution of a Markov chain by iteration."""
    if pi_seed is None:
        pi = np.ones(Pi.shape[0]) / Pi.shape[0]
    else:
        pi = pi_seed

    for it in range(maxit):
        pi_new = pi @ Pi
        if np.max(np.abs(pi_new - pi)) < tol:
            break
        pi = pi_new
    else:
        raise ValueError(f'No convergence after {maxit} forward iterations!')
    pi = pi_new

    return pi


def mean(x, pi):
    """Mean of discretized random variable with support x and probability mass function pi."""
    return np.sum(pi * x)


def variance(x, pi):
    """Variance of discretized random variable with support x and probability mass function pi."""
    return np.sum(pi * (x - np.sum(pi * x)) ** 2)


def std(x, pi):
    """Standard deviation of discretized random variable with support x and probability mass function pi."""
    return np.sqrt(variance(x, pi))


def cov(x, y, pi):
    """Covariance of two discretized random variables with supports x and y common probability mass function pi."""
    return np.sum(pi * (x - mean(x, pi)) * (y - mean(y, pi)))


def corr(x, y, pi):
    """Correlation of two discretized random variables with supports x and y common probability mass function pi."""
    return cov(x, y, pi) / (std(x, pi) * std(y, pi))


def markov_tauchen(rho, sigma, N=7, m=3):
    """Tauchen method discretizing AR(1) s_t = rho*s_(t-1) + eps_t.

    Parameters
    ----------
    rho   : scalar, persistence
    sigma : scalar, unconditional sd of s_t
    N     : int, number of states in discretized Markov process
    m     : scalar, discretized s goes from approx -m*sigma to m*sigma

    Returns
    ----------
    y  : array (N), states proportional to exp(s) s.t. E[y] = 1
    pi : array (N), stationary distribution of discretized process
    Pi : array (N*N), Markov matrix for discretized process
    """

    # make normalized grid, start with cross-sectional sd of 1
    s = np.linspace(-m, m, N)
    ds = s[1] - s[0]
    sd_innov = np.sqrt(1 - rho ** 2)

    # standard Tauchen method to generate Pi given N and m
    Pi = np.empty((N, N))
    Pi[:, 0] = norm.cdf(s[0] - rho * s + ds / 2, scale=sd_innov)
    Pi[:, -1] = 1 - norm.cdf(s[-1] - rho * s - ds / 2, scale=sd_innov)
    for j in range(1, N - 1):
        Pi[:, j] = (norm.cdf(s[j] - rho * s + ds / 2, scale=sd_innov) -
                    norm.cdf(s[j] - rho * s - ds / 2, scale=sd_innov))

    # invariant distribution and scaling
    pi = stationary(Pi)
    s *= (sigma / np.sqrt(variance(s, pi)))
    y = np.exp(s) / np.sum(pi * np.exp(s))

    return y, pi, Pi


def markov_rouwenhorst(rho, sigma, N=7):
    """Rouwenhorst method analog to markov_tauchen"""

    # parametrize Rouwenhorst for n=2
    p = (1 + rho) / 2
    Pi = np.array([[p, 1 - p], [1 - p, p]])

    # implement recursion to build from n=3 to n=N
    for n in range(3, N + 1):
        P1, P2, P3, P4 = (np.zeros((n, n)) for _ in range(4))
        P1[:-1, :-1] = p * Pi
        P2[:-1, 1:] = (1 - p) * Pi
        P3[1:, :-1] = (1 - p) * Pi
        P4[1:, 1:] = p * Pi
        Pi = P1 + P2 + P3 + P4
        Pi[1:-1] /= 2

    # invariant distribution and scaling
    pi = stationary(Pi)
    s = np.linspace(-1, 1, N)
    s *= (sigma     / np.sqrt(variance(s, pi)))
    y = np.exp(s) / np.sum(pi * np.exp(s))

    return y, pi, Pi


'''Part 5: njitted routines to speed up some steps in backward iteration or aggregation'''


@njit
def setmin(x, xmin):
    """Set 2-dimensional array x where each row is ascending equal to equal to max(x, xmin)."""
    ni, nj = x.shape
    for i in range(ni):
        for j in range(nj):
            if x[i, j] < xmin:
                x[i, j] = xmin
            else:
                break


@njit
def within_tolerance(x1, x2, tol):
    """Efficiently test max(abs(x1-x2)) <= tol for arrays of same dimensions x1, x2."""
    y1 = x1.ravel()
    y2 = x2.ravel()

    for i in range(y1.shape[0]):
        if np.abs(y1[i] - y2[i]) > tol:
            return False
    return True


@njit
def fast_aggregate(X, Y):
    """If X has dims (T, ...) and Y has dims (T, ...), do dot product for each T to get length-T vector.

    Identical to np.sum(X*Y, axis=(1,...,X.ndim-1)) but avoids costly creation of intermediates, useful
    for speeding up aggregation in td by factor of 4 to 5."""
    T = X.shape[0]
    Xnew = X.reshape(T, -1)
    Ynew = Y.reshape(T, -1)
    Z = np.empty(T)
    for t in range(T):
        Z[t] = Xnew[t, :] @ Ynew[t, :]
    return Z


'''Part 6: numerical differentiation'''


def numerical_diff(func, ssinputs_dict, shock_dict, h=1E-4, y_ss_list=None):
    """Differentiate function numerically via forward difference, i.e. calculate

    f'(xss)*shock = (f(xss + h*shock) - f(xss))/h

    for small h. (Variable names inspired by application of differentiating around ss.)

    Parameters
    ----------
    func            : function, 'f' to be differentiated
    ssinputs_dict   : dict, values in 'xss' around which to differentiate
    shock_dict      : dict, values in 'shock' for which we're taking derivative
                        (keys in shock_dict are weak subset of keys in ssinputs_dict)
    h               : [optional] scalar, scaling of forward difference 'h'
    y_ss_list       : [optional] list, value of y=f(xss) if we already have it

    Returns
    ----------
    dy_list : list, output f'(xss)*shock of numerical differentiation
    """
    # compute ss output if not supplied
    if y_ss_list is None:
        y_ss_list = make_tuple(func(**ssinputs_dict))

    # response to small shock
    shocked_inputs = {**ssinputs_dict, **{k: ssinputs_dict[k] + h * shock for k, shock in shock_dict.items()}}
    y_list = make_tuple(func(**shocked_inputs))

    # scale responses back up, dividing by h
    dy_list = [(y - y_ss) / h for y, y_ss in zip(y_list, y_ss_list)]

    return dy_list


def numerical_diff_symmetric(func, ssinputs_dict, shock_dict, h=1E-4):
    """Same as numerical_diff, but differentiate numerically using central (symmetric) difference, i.e.

    f'(xss)*shock = (f(xss + h*shock) - f(xss - h*shock))/(2*h)
    """

    # response to small shock in each direction
    shocked_inputs_up = {**ssinputs_dict, **{k: ssinputs_dict[k] + h * shock for k, shock in shock_dict.items()}}
    y_up_list = make_tuple(func(**shocked_inputs_up))

    shocked_inputs_down = {**ssinputs_dict, **{k: ssinputs_dict[k] - h * shock for k, shock in shock_dict.items()}}
    y_down_list = make_tuple(func(**shocked_inputs_down))

    # scale responses back up, dividing by h
    dy_list = [(y_up - y_down) / (2*h) for y_up, y_down in zip(y_up_list, y_down_list)]

    return dy_list


'''Part 7: simple nonlinear solvers'''


def newton_solver(f, x0, y0=None, tol=1E-9, maxcount=100, backtrack_c=0.5, noisy=True):
    """Simple line search solver for root x satisfying f(x)=0 using Newton direction.

    Backtracks if input invalid or improvement is not at least half the predicted improvement.

    Parameters
    ----------
    f               : function, to solve for f(x)=0, input and output are arrays of same length
    x0              : array (n), initial guess for x
    y0              : [optional] array (n), y0=f(x0), if already known
    tol             : [optional] scalar, solver exits successfully when |f(x)| < tol
    maxcount        : [optional] int, maximum number of Newton steps
    backtrack_c     : [optional] scalar, fraction to backtrack if step unsuccessful, i.e.
                        if we tried step from x to x+dx, now try x+backtrack_c*dx

    Returns
    ----------
    x       : array (n), (approximate) root of f(x)=0
    y       : array (n), y=f(x), satisfies |y| < tol
    """

    x, y = x0, y0
    if y is None:
        y = f(x)

    for count in range(maxcount):
        if noisy:
            printit(count, x, y)

        if np.max(np.abs(y)) < tol:
            return x, y

        J = obtain_J(f, x, y)
        dx = np.linalg.solve(J, -y)

        # backtrack at most 29 times
        for bcount in range(30):
            try:
                ynew = f(x + dx)
            except ValueError:
                if noisy:
                    print('backtracking\n')
                dx *= backtrack_c
            else:
                predicted_improvement = -np.sum((J @ dx) * y) * ((1 - 1 / 2 ** bcount) + 1) / 2
                actual_improvement = (np.sum(y ** 2) - np.sum(ynew ** 2)) / 2
                if actual_improvement < predicted_improvement / 2:
                    if noisy:
                        print('backtracking\n')
                    dx *= backtrack_c
                else:
                    y = ynew
                    x += dx
                    break
        else:
            raise ValueError('Too many backtracks, maybe bad initial guess?')
    else:
        raise ValueError(f'No convergence after {maxcount} iterations')


def broyden_solver(f, x0, y0=None, tol=1E-9, maxcount=100, backtrack_c=0.5, noisy=True):
    """Similar to newton_solver, but solves f(x)=0 using approximate rather than exact Newton direction,
    obtaining approximate Jacobian J=f'(x) from Broyden updating (starting from exact Newton at f'(x0)).

    Backtracks only if error raised by evaluation of f, since improvement criterion no longer guaranteed
    to work for any amount of backtracking if Jacobian not exact.
    """

    x, y = x0, y0
    if y is None:
        y = f(x)

    # initialize J with Newton!
    J = obtain_J(f, x, y)
    for count in range(maxcount):
        if noisy:
            printit(count, x, y)

        if np.max(np.abs(y)) < tol:
            return x, y

        dx = np.linalg.solve(J, -y)

        # backtrack at most 29 times
        for bcount in range(30):
            # note: can't test for improvement with Broyden because maybe
            # the function doesn't improve locally in this direction, since
            # J isn't the exact Jacobian
            try:
                ynew = f(x + dx)
            except ValueError:
                if noisy:
                    print('backtracking\n')
                dx *= backtrack_c
            else:
                J = broyden_update(J, dx, ynew - y)
                y = ynew
                x += dx
                break
        else:
            raise ValueError('Too many backtracks, maybe bad initial guess?')
    else:
        raise ValueError(f'No convergence after {maxcount} iterations')


def obtain_J(f, x, y, h=1E-5):
    """Finds Jacobian f'(x) around y=f(x)"""
    nx = x.shape[0]
    ny = y.shape[0]
    J = np.empty((nx, ny))

    for i in range(nx):
        dx = h * (np.arange(nx) == i)
        J[:, i] = (f(x + dx) - y) / h
    return J


def broyden_update(J, dx, dy):
    """Returns Broyden update to approximate Jacobian J, given that last change in inputs to function
    was dx and led to output change of dy."""
    return J + np.outer(((dy - J @ dx) / np.linalg.norm(dx) ** 2), dx)


def printit(it, x, y, **kwargs):
    """Convenience printing function for noisy iterations"""
    print(f'On iteration {it}')
    print(('x = %.3f' + ',%.3f' * (len(x) - 1)) % tuple(x))
    print(('y = %.3f' + ',%.3f' * (len(y) - 1)) % tuple(y))
    for kw, val in kwargs.items():
        print(f'{kw} = {val:.3f}')
    print('\n')


'''Part 8: topological sort and related code'''


def block_sort(block_list, findrequired=False):
    """Given list of blocks (either blocks themselves or dicts of Jacobians), find a topological sort and also
    optionally return which outputs must be computed as inputs of later blocks.

    Relies on blocks having 'inputs' and 'outputs' attributes (unless they are dicts of Jacobians, in which case it's
    inferred) that indicate their aggregate inputs and outputs"""
    # step 1: map outputs to blocks for topological sort
    outmap = dict()
    for num, block in enumerate(block_list):
        if hasattr(block, 'outputs'):
            outputs = block.outputs
        elif isinstance(block, dict):
            outputs = block.keys()
        else:
            raise ValueError(f'{block} is not recognized as block or does not provide outputs')

        for o in outputs:
            if o in outmap:
                raise ValueError(f'{o} is output twice')
            outmap[o] = num

    # step 2: dependency graph for topological sort and input list
    dep = {num: set() for num in range(len(block_list))}
    if findrequired:
        required = set()
    for num, block in enumerate(block_list):
        if hasattr(block, 'inputs'):
            inputs = block.inputs
        else:
            inputs = set(i for o in block for i in block[o])

        for i in inputs:
            if i in outmap:
                dep[num].add(outmap[i])
                if findrequired:
                    required.add(i)

    # step 3: return topological sort, also 'required' if wanted
    if findrequired:
        return topological_sort(dep), required
    else:
        return topological_sort(dep)


def topological_sort(dep, names=None):
    """Given directed graph pointing from each node to the nodes it depends on, topologically sort nodes"""

    # get complete set version of dep, and its reversal, and build initial stack of nodes with no dependencies
    dep, revdep = complete_reverse_graph(dep)
    nodeps = [n for n in dep if not dep[n]]
    topsorted = []

    # Kahn's algorithm: find something with no dependency, delete its edges and update
    while nodeps:
        n = nodeps.pop()
        topsorted.append(n)
        for n2 in revdep[n]:
            dep[n2].remove(n)
            if not dep[n2]:
                nodeps.append(n2)

    # should be done: topsorted should be topologically sorted with same # of elements as original graphs!
    if len(topsorted) != len(dep):
        cycle_ints = find_cycle(dep, dep.keys() - set(topsorted))
        assert cycle_ints is not None, 'topological sort failed but no cycle, THIS SHOULD NEVER EVER HAPPEN'
        cycle = [names[i] for i in cycle_ints] if names else cycle_ints
        raise Exception(f'Topological sort failed: cyclic dependency {" -> ".join(cycle)}')

    return topsorted


def complete_reverse_graph(gph):
    """Given directed graph represented as a dict from nodes to iterables of nodes, return representation of graph that
    is complete (i.e. has each vertex pointing to some iterable, even if empty), and a complete version of reversed too.
    Have returns be sets, for easy removal"""

    revgph = {n: set() for n in gph}
    for n, e in gph.items():
        for n2 in e:
            n2_edges = revgph.setdefault(n2, set())
            n2_edges.add(n)

    gph_missing_n = revgph.keys() - gph.keys()
    gph = {**{k: set(v) for k, v in gph.items()}, **{n: set() for n in gph_missing_n}}
    return gph, revgph


def find_cycle(dep, onlyset=None):
    """Return list giving cycle if there is one, otherwise None"""

    # supposed to look only within 'onlyset', so filter out everything else
    if onlyset is not None:
        dep = {k: (set(v) & set(onlyset)) for k, v in dep.items() if k in onlyset}

    tovisit = set(dep.keys())
    stack = SetStack()
    while tovisit or stack:
        if stack:
            # if stack has something, still need to proceed with DFS
            n = stack.top()
            if dep[n]:
                # if there are any dependencies left, let's look at them
                n2 = dep[n].pop()
                if n2 in stack:
                    # we have a cycle, since this is already in our stack
                    i2loc = stack.index(n2)
                    return stack[i2loc:] + [stack[i2loc]]
                else:
                    # no cycle, visit this node only if we haven't already visited it
                    if n2 in tovisit:
                        tovisit.remove(n2)
                        stack.add(n2)
            else:
                # if no dependencies left, then we're done with this node, so let's forget about it
                stack.pop(n)
        else:
            # nothing left on stack, let's start the DFS from something new
            n = tovisit.pop()
            stack.add(n)

    # if we never find a cycle, we're done
    return None


class SetStack:
    """Stack implemented with list but tests membership with set to be efficient in big cases"""

    def __init__(self):
        self.myset = set()
        self.mylist = []

    def add(self, x):
        self.myset.add(x)
        self.mylist.append(x)

    def pop(self):
        x = self.mylist.pop()
        self.myset.remove(x)
        return x

    def top(self):
        return self.mylist[-1]

    def index(self, x):
        return self.mylist.index(x)

    def __contains__(self, x):
        return x in self.myset

    def __len__(self):
        return len(self.mylist)

    def __getitem__(self, i):
        return self.mylist.__getitem__(i)

    def __repr__(self):
        return self.mylist.__repr__()


'''Part 9: Assorted other utilities'''


def make_tuple(x):
    """If not tuple or list, make into tuple with one element.

    Wrapping with this allows user to write, e.g.:
    "return r" rather than "return (r,)"
    "policy='a'" rather than "policy=('a',)"
    """
    return (x,) if not (isinstance(x, tuple) or isinstance(x, list)) else x


def input_list(f):
    """Return list of function inputs"""
    return inspect.getfullargspec(f).args


def output_list(f):
    """Scans source code of function to detect statement like

    'return L, Div'

    and reports the list ['L', 'Div'].

    Important to write functions in this way when they will be scanned by output_list, for
    either SimpleBlock or HetBlock.
    """
    return re.findall('return (.*?)\n', inspect.getsource(f))[-1].replace(' ', '').split(',')


def demean(x):
    return x - x.sum()/x.size


# simpler aliases for LU factorization and solution
def factor(X):
    return scipy.linalg.lu_factor(X)


def factored_solve(Z, y):
    return scipy.linalg.lu_solve(Z, y)


# functions for handling saved Jacobians: extract keys from dicts or key pairs
# from nested dicts, and take subarrays with 'shape' of the values
def extract_dict(savedA, keys, shape):
    return {k: take_subarray(savedA[k], shape) for k in keys}


def extract_nested_dict(savedA, keys1, keys2, shape):
    return {k1: {k2: take_subarray(savedA[k1][k2], shape) for k2 in keys2} for k1 in keys1}


def take_subarray(A, shape):
    # verify leading dimensions of A are >= shape
    if not all(m <= n for m, n in zip(shape, A.shape)):
        raise ValueError(f'Saved has dimensions {A.shape}, want larger {shape} subarray')

    # take subarray along those dimensions: A[:shape, ...]
    return A[tuple(slice(None, x, None) for x in shape) + (Ellipsis,)]
